CN1331362C - Picture correction method, picture correction apparatus and cathode-ray tube displaying device - Google Patents

Abstract

This invention introduces an image correction method, an image correction device, and a CRT display device to lower the consumed power required to correct images during a long period of use time. After microcomputer 2 provides power source to the CRT, it commands the corrected current to decrease monotonously as time passes to calculate the value of the corrected current. Drivers 3 to 7, 22 generate corrected output currents based on the values of the corrected currents calculated by the microcomputer 2. The correction device C assembled at the CRT receives the corrected currents from the drivers 3 to 7, 22 and then corrects the displayed image on the CRT.

Description

Method for correcting image, image correction apparatus and cathode-ray tube displaying device

Technical field

The present invention relates to proofread and correct and for example be shown in cathode ray tube (CRT: the image correcting method of the image cathode ray tube) and picture correction apparatus and the cathode-ray tube displaying device that adopts this method and apparatus.

Background technology

Figure 24 is a block diagram of representing picture correction apparatus in the past.Picture correction apparatus shown in Figure 24 comprise CR timer 1, microcomputer 2a, driver 3～7, first～the 4th screen correcting coil (hereinafter referred to as the screen correcting coil) 8～11, convergence correction with coil (hereinafter referred to as the convergence correction coil) 12.First～the 4th screen correcting coil 8～11 and convergence correction coil 12 be installed on the cathode ray tube (not shown).

If connect the power supply (the following moment with the cathode ray tube energized is called ' power source ON ') of cathode ray tube, so cathode ray tube screen and convergence begin to occur deterioration, if cut off the power supply (the following moment that will cut off the cathode ray tube power supply be called ' power supply OFF ') of cathode ray tube, its deterioration begins recovery so.Still cut off its power supply when no matter connecting the power supply of cathode ray tube, the degradation signal TS of CR timer 1 output usually carries out work, output and screen and the corresponding degradation signal TS of convergence degradation.

Microcomputer 2a is beginning elapsed time from power source ON, according to the correcting current value of degradation signal TS calculating optimum.Driver 3～7 make the correcting current of the value of calculating as microcomputer 2a flow into first～the 4th in screen correcting coil 8～11, the convergence correction coil 12.First～the 4th screen correcting coil 8～11, convergence correction coil 12 suitably regulating screen according to correcting current and assembling.

As above, picture correction apparatus is by supplying with correcting current to cathode ray tube, automatically proofread and correct by the image of cathode-ray tube display screen and assembling.

Figure 25 and Figure 26 represent respectively after the power source ON state and from this state begin through adequate time (for example 3 hours) state screen and the variation in the past assembled.As Figure 25 and shown in Figure 26, after power source ON, the deterioration that is not having screen and assembling, image is displayed on the position of expectation the variable quantity minimum (zero) of the position of image expectation (in other words, apart from).So the state that image is displayed on desired locations is called optimum state, with this moment screen state and converged state be called best screen, the best convergence.

Begin along with the time increases from power source ON, screen and assemble continuous deterioration, with the location dislocation ground displayed image of expectation.And if begin through adequate time (for example 3 hours) from power source ON, the deterioration of do that screen and convergence becomes saturation condition, and the variable quantity of the visual desired locations of distance becomes maximum.

For example, as shown in figure 25, as time goes by, the upper left of image is from position (direction F) constantly skew from left to right of expectation after power source ON.If in this case, by make suitable electric current in order to the corrected image upper left flow in the screen correcting coil, the rightabout of the upper left direction F of image is moved, and can be that image is presented on the position of expectation with optimum state so.

Figure 27 represents to begin elapsed time (elapsed time) and correcting current and apart from the relation in the past between the variable quantity of visual desired locations from power source ON.As shown in figure 27, in the past,,, will increase correcting current through after a while in order often to keep optimum state.

But after passing through the sufficient time from power source ON, correcting current usually flows by maximum.Therefore, under the situation of long-time use cathode ray tube, there are the many problems of this part power consumption.

Summary of the invention

In order to address the above problem, the object of the present invention is to provide image correcting method and the picture correction apparatus and the cathode-ray tube displaying device of the required power consumption of image correcting in the time of can reducing to use for a long time.

The problem solution of the present invention's first scheme is a kind of by supplying with correcting current to cathode ray tube, automatically proofread and correct the method for the image of described cathode-ray tube display, it is characterized in that, after the power supply of connecting described cathode ray tube,, make the constantly dull minimizing of described correcting current along with the time increases.

The problem solution of alternative plan of the present invention is characterised in that, behind the power supply of connecting described cathode ray tube, along with the time increases, constantly reduces the minimizing ratio of described correcting current.

The problem solution of third party's case of the present invention is characterised in that from connecting the power supply of described cathode ray tube, correcting current shown in making is constantly near zero.

In the problem solution of cubic case of the present invention, comprising in screen, convergence and the horizontal position of image at least one from the object of the described image of dynamic(al) correction.

The problem solving device of the 5th scheme of the present invention is a kind of like this picture correction apparatus, this device is by supplying with correcting current to cathode ray tube, image from the described cathode-ray tube display of dynamic(al) correction, behind the power supply of connecting described cathode ray tube, in order to increase along with the time, make the constantly dull minimizing of described correcting current, this device is furnished with the counting circuit of calculating described correcting current value, the driver that the result generates described correcting current of calculating according to described counting circuit, with be arranged on the described cathode ray tube, acceptance is proofreaied and correct by the adjuster of the image of described cathode-ray tube display from the described correcting current of described driver.

In the problem solving device of the 6th scheme of the present invention, behind the power supply of connecting described cathode ray tube, described counting circuit is calculated the value of described correcting current, so that along with the time increases, constantly reduce the minimizing ratio of described correcting current.

In the problem solving device of the 7th scheme of the present invention, behind the power supply of connecting described cathode ray tube, described counting circuit is calculated described correcting current value, so that make described correcting current constantly near zero.

In the problem solving device of all directions of the present invention case, described means for correcting is comprising at least one of shielding in correcting coil, convergence correction coil and the horizontal image position correction usefulness deflecting coil.

The problem solving device of the 9th scheme of the present invention also comprises in order to make described counting circuit calculate described correcting current value provides necessary data from the outside outside terminal.

The problem solving device of the tenth scheme of the present invention comprises any described picture correction apparatus and described cathode ray tube in the scheme 5 to 9.

Description of drawings

Fig. 1 is the figure of explanation picture correction apparatus work of the present invention.

Fig. 2 is the figure of explanation picture correction apparatus work of the present invention.

Fig. 3 is the figure of explanation picture correction apparatus work of the present invention.

Fig. 4 is an oblique view of schematically representing the means for correcting of the embodiment of the invention.

Fig. 5 is the block diagram of the picture correction apparatus of the expression embodiment of the invention.

Fig. 6 is the flow chart of the image correcting method of the expression embodiment of the invention.

Fig. 7 is the flow chart of the image correcting method of the expression embodiment of the invention.

Fig. 8 is the flow chart of the image correcting method of the expression embodiment of the invention.

Fig. 9 is the flow chart of the image correcting method of the expression embodiment of the invention.

Figure 10 is the flow chart of the image correcting method of the expression embodiment of the invention.

Figure 11 is the flow chart of the image correcting method of the expression embodiment of the invention.

Figure 12 is the figure of the picture correction apparatus work of the explanation embodiment of the invention.

Figure 13 is the figure of the picture correction apparatus work of the explanation embodiment of the invention.

Figure 14 is the figure of the picture correction apparatus work of the explanation embodiment of the invention.

Figure 15 is the figure of the picture correction apparatus work of the explanation embodiment of the invention.

Figure 16 is the figure of the picture correction apparatus work of the explanation embodiment of the invention.

Figure 17 is the figure of the picture correction apparatus work of the explanation embodiment of the invention.

Figure 18 is the figure of the picture correction apparatus work of the explanation embodiment of the invention.

Figure 19 is the figure of the picture correction apparatus work of the explanation embodiment of the invention.

Figure 20 is the figure of the picture correction apparatus work of the explanation embodiment of the invention.

Figure 21 is the figure of the picture correction apparatus work of the explanation embodiment of the invention.

Figure 22 is the figure of the picture correction apparatus work of the explanation embodiment of the invention.

Figure 23 is the figure of the picture correction apparatus work of the explanation embodiment of the invention.

Figure 24 is a block diagram of representing picture correction apparatus in the past.

Figure 25 is the figure that picture correction apparatus work in the past is described.

Figure 26 is the figure that picture correction apparatus work in the past is described.

Figure 27 is the figure that picture correction apparatus work in the past is described.

Embodiment

Figure 25 and Figure 26 represent the feature of cathode ray tube in the past.In other words, in the past, after power source ON, optimum state i.e. image was displayed on the position of expectation.And, begin along with the time increases from power source ON, screen and assemble continuous deterioration, image shows from the location dislocation of expectation.And, if begin through adequate time (for example 3 hours), do that screen and the deterioration the assembled state that reaches capacity from power source ON, reach maximum apart from the variable quantity of visual desired locations.

Relative therewith, in the present invention, use cathode ray tube with feature illustrated in figures 1 and 2.In other words, in the present invention, with opposite in the past, after power source ON, image shows from desired location dislocation ground.And, after power source ON, increasing along with the time, the position alignment of screen and convergence etc. becomes bad, has an effect of returning but this change is bad, and image is constantly near the position of expectation.And, if begin through adequate time (for example 3 hours) from power source ON, the deterioration of the position alignment state that reaches capacity so, but this moment, optimum state i.e. image is displayed on the position of expectation.

Have again, because it is different with the relative position relation of desired locations that above-mentioned cathode ray tube in the past and the substantive difference that is used for the present invention's cathode ray tube are the display surface 100 of cathode-ray tube display image, so the cathode ray tube that can use technology in the past to be used in the present invention.

Fig. 3 represents the relation that begins the variable quantity of elapsed time (elapsed time) and correcting current and the visual desired locations of distance from power source ON of the present invention.In the present invention, for example, as shown in Figure 1 because the upper left of image does not reach the position of expectation after power source ON, so be provided with in order to the upper left of corrected image the suitable correcting current that flows in the screen correcting coil.Therefore, the upper left of image being moved to the rightabout of direction F, is that image is presented on the position of expectation with optimum state.And, begin along with the time increases from power source ON, screen and constantly become bad, the upper left of image is (direction F) skew from left to right.Therefore, if by reducing correcting current, the upper left of image is moved to the rightabout of direction F, even begin also can keep optimum state from power source ON so through certain hour.Therefore, and begin from power source ON to increase and the situation in the past that increases correcting current is compared along with the time, it is abundant more to begin elapsed time from power source ON, can reduce the desired power consumption of image correcting more.

Particularly many cathode-ray tube displaying devices (for example, as computer display and television set etc., the situation that comprises cathode ray tube) when the user mode of the power supply of connecting cathode ray tube continuously for a long time, the reduction effect of the power consumption that the present invention produces becomes more remarkable.

Below, illustrate in greater detail embodiments of the invention.

Fig. 4 is an oblique view of schematically representing to be used to proofread and correct the means for correcting C of the image on the display surface 100 that is shown in cathode ray tube 24.Means for correcting C is installed on the cathode ray tube 24, in Fig. 4, comprise first～the 4th screen correcting coil 8～11, convergence correction coil 12 and horizontal image position correction deflecting coil (hereinafter referred to as deflecting coil) 23.Convergence correction coil 12 is installed in the neck part of cathode ray tube 24, and deflecting coil 23 is installed in the root of neck part, and first～the 4th screen correcting coil 8～11 be installed in four jiaos of display surface 100.

Fig. 5 is the block diagram of the picture correction apparatus structure of the expression embodiment of the invention.Picture correction apparatus shown in Figure 5 comprise CR timer 1, memory 13, microcomputer 2, driver 3～7,22, first～the 4th screen correcting coil 8～11, convergence correction coil 12 and deflecting coil 23.Microcomputer 2 comprises A/D converter 14, central processing unit (below be designated as CPU) 15, D/A converter 16～21, outside terminal P1～P3.

Deterioration corresponding to the position alignment of cathode ray tube 24 (wherein, being become by screen, convergence and level image set of locations) is provided with CR timer 1.In other words, in case cathode ray tube 24 has the deterioration that energized just begins to produce position alignment, and in case its deterioration of cutting off the electricity supply just begins the feature recovered.The characteristic curve C2 of Figure 21 represents the relation of the degradation AG of elapsed time and position alignment.Specifically, degradation AG is being used for cathode ray tube 24 of the present invention according to the variable quantity apart from visual desired locations, and degradation AG is big more, and image just is not easy the position near expectation more.Have again, in Figure 21, be illustrated under the state that the deterioration of position alignment recovers fully, connect the situation of the power supply of cathode ray tube 24.

On the other hand, degradation value TDS and the degradation AG of the degradation signal TS of CR timer 1 change accordingly, in case have the power supply of connecting cathode ray tube 24, just begin to reduce, and just begin the feature that increases in case cut off the electricity supply.In addition, since degradation AG have about exponential function promptly to begin elapsed time from power source ON long more, just become more little feature with respect to the variation ratio of time AG, thus relative therewith, the degradation value TDS of degradation signal TS is also changed by exponential function.So, generate degradation value TDS in order to press exponential function, well-known in design CR timer 1, if the integrating circuit that for example utilizes capacitor and resistance to constitute so just can be realized.

As described above, deterioration according to position alignment is provided with CR timer 1, when the power supply of no matter connecting cathode ray tube 24 still cuts off its power supply, all carry out work, the corresponding degradation signal TS of degradation AG of output and the position alignment of cathode ray tube 24.

Then, memory 13 shown in Figure 5 for example is ROM (read-only memory) etc., stores microcomputer 2 in advance and calculates the needed data M D of suitable correcting current value according to the deterioration of the position alignment of cathode ray tube 24.

The data M D that is stored in the memory 13 offers outside terminal P1, offers outside terminal P2 from the degradation signal TS of CR timer 1, and other necessary signal (for example, horizontal deflection signal HSYNC) offers outside terminal P3.

In microcomputer 2, A/D converter 14 converts degradation signal TS to for example degradation value TDS of 0～255 scope.CPU 15 accepts data M D, degradation value TDS and horizontal deflection signal HSYNC etc., according to they calculate supply with first～the 4th current value cpurity1, cpurity2, cpurity3, cpurity4, hsta, the hposi (scope for example is 0～255) of correcting current of screen correcting coil 8～11, convergence correction coil 12 and deflecting coil 23.D/A converter 16～21 converts current value cpurity1, cpurity2, cpurity3, cpurity4, hsta, hposi to analog signal.

Driver 3～7,22 generates correcting current and the output of using the current value of representing from the analog signal of D/A converter 16～21, first～the 4th flow in screen correcting coil 8～11, convergence correction coil 12 and the deflecting coil 23.First～the 4th screen correcting coil 8～11, convergence correction coil 12 and deflecting coil 23 suitably regulating screen according to correcting current and assembling.

As mentioned above, the picture correction apparatus of the embodiment of the invention is automatically proofreaied and correct the position alignment that is shown in the image on the cathode ray tube by supplying with correcting current to cathode ray tube 24.

Below, illustrate that CPU 15 is used to calculate the executive software (computer program) of current value cpurity1, cpurity2, cpurity3, cpurity4, hsta, hposi (scope for example is 0～255).Fig. 6 is the flow chart of main program that is used to calculate correcting current of expression computer program.

If carry out main program (beginning), so at first carry out get-timer subprogram S2, in this subprogram, calculate the degradation value cr-steady of filtering current time degradation value TDS.Then, according to degradation value cr-steady, carry out carrying out that screen proofreaies and correct screen aligning step CPS, carry out convergence correction convergence correction step HSS, carry out the horizontal image position correction step HPS of horizontal image position correction, finish main program then.And, as shown in figure 21, from power source ON to power supply OFF ..., as moment t1, t2, t3, t4 ... like that periodically repeat above main program.

Screen aligning step CPS and comprise CPURITY-ENABLE step S3, step S4, calc-cpurity subprogram S5.In CPURITY-ENABLE step S3, degradation value cr-steady and expected value cr-center (deterioration of position alignment is the expected value of the degradation value cr-steady of saturation condition, for example, is 100 in Figure 21) are compared.If degradation value cr-steady than expected value cr-center big (yes), owing to be unsaturated state, proofreaies and correct so screen is being carried out in judgement so,, owing to be saturation condition,, judgement proofreaies and correct so so not carrying out screen if not (no) like this.Do not carrying out timing (no), current value cpurity1, cpurity2, cpurity3, the cpurity4 that inputs to D/A converter 16～19 is being set at not corrected value cpurity1-fact, cpurity2-fact, cpurity3-fact, the cpurity4-fact (step S4) that does not carry out timing.On the other hand, carrying out timing (yes), setting current value cpurity1, cpurity2, cpurity3, cpurity4 than t3 last time little (calc-cpurity subprogram S5).

Convergence correction step HSS comprises HSTA-ENABLE step S6, step S7, calc-hsta subprogram S8.In HSTA-ENABLE step S6, degradation value cr-steady and expected value cr-center are compared.If degradation value cr-steady is than expected value cr-center big (yes), so owing to being unsaturated state, so convergence correction is carried out in judgement, if not (no) like this, so owing to being saturation condition, so convergence correction is not carried out in judgement.Do not carrying out timing (no), the current value hsta that inputs to D/A converter 20 is being set at the not corrected value hsta-fact (step S7) that does not carry out timing.On the other hand, carrying out timing (yes), setting current value hsta than t3 last time little (calc-hsta subprogram S8).

Horizontal image position correction step HPS comprises HPOSI-ENABLE step S9, step S10, calc-hposi subprogram S11.In HPOSI-ENABLE step S9, degradation value cr-steady and expected value cr-center are compared.If degradation value cr-steady is than expected value cr-center big (yes), so owing to being unsaturated state, so horizontal image position correction is carried out in judgement, if not (no) like this, so owing to being saturation condition, so horizontal image position correction is not carried out in judgement.Do not carrying out timing (no), the current value hposi that inputs to D/A converter 21 is being set at the not corrected value hposi-fact (step S10) that does not carry out timing.On the other hand, carrying out timing (yes), setting current value hposi than t3 last time little (calc-hposi subprogram S11).

Fig. 7 represents get-timer subprogram S2.Get-timer subprogram S2 comprises get-timer-delta subprogram S12.Get-timer-delta subprogram S12 is and calc-cpurity subprogram S5, calc-hsta subprogram S8, the shared slave module of calc-hposi subprogram S11, and purpose is to calculate the time that the reaches capacity time-delta (deterioration from this t4 to position alignment reach capacity during) of this necessary in calc-cpurity subprogram S5, calc-hsta subprogram S8, calc-hposi subprogram S11 t4.Because the degradation value cr-steady of the original purpose of conduct of get-timer subprogram S2 fetches function and reaches capacity the confidential relation of having calculated of time time-delta, so comprise this slave module.If begin to carry out get-timer subprogram S2, so just begin to carry out get-timer-delta subprogram S12, calculate the degradation value cr-steady of this t4 and the time time-delta that reaches capacity.And, if get-timer-delta subprogram S12 finishes, return main program so.

Fig. 8 represents get-timer-delta subprogram S12.Subprogram S12 comprises the step S121 that calculates this degradation value cr-steady and calculates the step S122 of the time time-delta that reaches capacity.

At first, if description of step S121, CPU 15 takes out degradation value TDS and the storage of this t4 so.And, for example calculate the mean value TIME-ave of nearest four times (t4, t3, t2, t1) degradation value TDS, substitution degradation value cr-Timer.

Because the deterioration of position alignment for example needed change lentamente in 3 hours, so that the return period of main program is very short, if shorten last time t3 with time difference of this t4, so last time t3 the difference of degradation value cr-Timer (degradation value cr-steady) and the degradation value cr-Timer of this t4 almost approach zero.But big if the error of A/D converter 14 (Fig. 5) becomes, the difference of degradation value cr-steady and degradation value cr-Timer becomes big so.Therefore, judge that the absolute value of difference of degradation value cr-steady and degradation value cr-Timer is whether in permissible value TIMER-ADC-TOL (step S14).If in permissible value TIMER-ADC-TOL (yes), the degradation value cr-Timer of this t4 is normal so, degradation value cr-steady is updated to the degradation value cr-Timer (step S15) of this t4.On the other hand, (no) if not so, the degradation value cr-Timer of this t4 is unusual so, and the degradation value cr-Timer of t3 was set at the degradation value cr-Timer of this t4 with last time.And, will be defined as the value (step S16) of this t4 through the degradation value cr-Timer of above step S14 or step S15.

As described above, calculate the mean value TIME-ave of nearest four times degradation value TDS, compare by absolute value and permissible value TIMER-ADC-TOL simultaneously, calculate the degradation value cr-steady of filtering current time degradation value TDS the difference of degradation value cr-steady and degradation value cr-Time.Thus, even the error of A/D converter 14 is big, picture correction apparatus also can steady operation.

Then, if description of step S122 in TIMER-ENABLE step S17, compares degradation value cr-steady and expected value cr-center so.If degradation value cr-steady is judged as unsaturated state so than expected value cr-center big (yes), (no) then is judged as saturation condition if not so.During saturation condition (no), with the zero substitution time time-delta (step S19) that reaches capacity.On the other hand, not when saturation condition (yes), the value substitution that will from degradation value cr-steady, deduct expected value cr-center reach capacity (step S18) among the time time-delta.Resemble and calculate the time time-delta that reaches capacity above.

Then, Fig. 9 represents calc-cpurity subprogram S5.Calc-cpurity subprogram S5 comprises the step S20 that obtains current value cpurity1, cpurity2, cpurity3, cpurity4.If begin to carry out calc-cpurity subprogram S5, so with regard to execution in step S20.In step S20, calculate for example current value cpurity1, cpurity2, cpurity3, the cpurity4 of 0～255 scope according to formula 1～formula 4.And, if step S20 finishes, return main program so.

[mathematical expression 1]

Cpurity1=ADJ-CPURITY1+{CPURITY1-GAIN * CPURITY1-POL * time-delta}...... (formula 1)

Cpurity2=ADJ-CPURITY2+{CPURITY2-GAIN * CPURITY2-POL * time-delta}...... (formula 2)

Cpurity3=ADJ-CPURITY3+{CPURITY3-GAIN * CPURITY3-POL * time-delta}...... (formula 3)

Cpurity4=ADJ-CPURITY4+{CPURITY4-GAIN * CPURITY4-POL * time-delta}...... (formula 4)

Have, in formula 1～formula 4, ADJ-CPURITY1, ADJ-CPURITY2, ADJ-CPURITY3, ADJ-CPURITY4 are the offsets of current value cpurity1, cpurity2, cpurity3, cpurity4 again.In addition, CPURITY1-GAIN, CPURITY2-GAIN, CPURITY3-GAIN, CPURITY4-GAIN represent current value cpurity1, cpurity2, cpurity3, the cpurity4 variation ratio (gain) with respect to degradation value TDS.In addition, CPURITY1-POL, CPURITY2-POL, CPURITY3-POL, CPURITY4-POL are the polarity numbers (1 or+1) of gain CPURITY1-GAIN, CPURITY2-GAIN, CPURITY3-GAIN, CPURITY4-GAIN.

Below, Figure 10 represents calc-hsta subprogram S8.Calc-hsta subprogram S8 comprises the step S21 that obtains current value hsta.If begin to carry out calc-hsta subprogram S8, so with regard to execution in step S21.In step S21, calculate for example current value hsta of 0～255 scope according to formula 5.And, if step S21 finishes, return main program so.

[mathematical expression 2]

Hsta=ADJ-HSTA+{HSTA-GAIN * HSTA-POL * time-delta}...... (formula 5)

Have, in formula 5, ADJ-HSTA is the offset of current value hsta again.In addition, HSTA-GAIN represents the variation ratio (gain) of current value hsta with respect to degradation value TDS.In addition, HSTA-POL is the polarity number (1 or+1) of gain HSTA-GAIN.

Below, Figure 11 represents calc-hposi subprogram S11.Calc-hposi subprogram S11 comprises the step S22 that obtains current value hposi.If begin to carry out calc-hposi subprogram S11, so with regard to execution in step S22.In step S22, calculate for example current value hposi of 0～255 scope according to formula 6.And, if step S22 finishes, return main program so.

[mathematical expression 3]

Hposi=ADJ-HPOSI+{HPOSI-GAIN * HPOSI-POL * time-delta}...... (formula 6)

Have, in formula 6, ADJ-HPOSI is the offset of current value hposi again.In addition, HPOSI-GAIN represents the variation ratio (gain) of current value hposi for degradation value TDS.In addition, HPOSI-POL is the polarity number (1 or+1) of gain HPOSI-GAIN.

More than Shuo Ming offset, yield value and polarity number are for example tried to achieve by simulating suitably, can set before cathode-ray tube displaying device is offered market.Have, for offset, utilize the adjustment knob (not shown) that is arranged in the cathode-ray tube displaying device, the user can easily change.Therefore, user's side can at random finely tuned screen, convergence and horizontal position of image.In addition, by gaining and polarity number suitably is set in supplier's side in advance, can be best from dynamic(al) correction from any time that power source ON begins screen, convergence and horizontal position of image.

More than, as the explanation of Fig. 4～Figure 11, by reducing correcting current, from power source ON, as long as, just can reduce the desired power consumption of image correcting through adequate time.

In addition, microcomputer 2 is accepted the degradation value TDS of expression cathode ray tube 24 position alignment degradations in real time, calculate the current value of best correcting current with computer, the correction of frequent good the screen that can automatically carry out beginning from power source ON, convergence, horizontal position of image.

And according to the feature of cathode ray tube 24, along with the increase of time, the ratio that deterioration increases constantly diminishes after the power supply of connecting cathode ray tube 24.Relative therewith, along with the carrying out of time, the minimizing ratio of the correcting current of driver 4～7,22 outputs constantly reduces.Therefore, the correction position deterioration of aiming at suitably.

Below, describing necessary parameter among screen aligning step CPS, convergence correction step HSS and the horizontal image position correction step HPS in detail.Have, below explanation is the situation that cathode ray tube 24 is used for computer again.

At first, necessary parameter has polarity number CPURITY1-POL, CPURITY2-POL, CPURITY3-POL, CPURITY4-POL, gain CPURITY1-GAIN, CPURITY2-GAIN, CPURITY3-GAIN, CPURITY4-GAIN, not corrected value cuprity1-fact, cuprity2-fact, cuprity3-fact, cuprity4-fact in screen aligning step CPS.

Specifically, consider to resemble situation about changing as shown in Figure 13 along with cathode ray tube 24 elapsed times increase.After power source ON, upper left and the bottom left section that is shown in the image on the display surface 100 is positioned at than the desired locations part of keeping right, and the upper right and lower right-most portion that is presented at the image on the display surface 100 is in than the desired locations part that keeps left, and is 10 μ m apart from the variable quantity of its desired locations.In addition, from power source ON, during through adequate time, four jiaos of positions (being that variable quantity is 0 μ m) that are in expectation of the image of display surface 100.

Under the situation of above-mentioned concrete example, if enumerate an example that begins often to keep optimum state from power source ON, so at first on hardware, as Figure 12 and shown in Figure 4, with first～the 4th screen correcting coil 8～11 be installed in four jiaos of cathode ray tube 24, so that each first～the 4th when flowing through the forward correcting current in the screen correcting coil 8～11, move image towards the direction of arrow F four jiaos.In addition, if input to current value cpurity1, cpurity2, cpurity3, the cpurity4 of D/A converter 16～19 (Fig. 5) ± 1 variation taking place, carry out circuit design so, makes the correcting current value variation ± 1.0mA of driver 3～6 outputs.And, be that if current value cpurity1, cpurity2, cpurity3, cpurity4 take place ± 1 and change, the image of display surface 100 only moves for four jiaos and is so for the measured result of the cathode-ray tube displaying device of making | the absolute value of 1.0 μ m|.In addition, degradation value TDS as shown in figure 21.In this case, can press

CPURITY1-POL＝+1

CPURITY2-POL＝-1

CPURITY3-POL＝-1

CPURITY4-POL＝+1

CPURITY1-GAIN＝10/140

CPURITY2-GAIN＝10/140

CPURITY3-GAIN＝10/140

CPURITY4-GAIN＝10/140

Set.

Polarity number CPURITY1-POL, CPURITY2-POL, CPURITY3-POL, CPURITY4-POL represent the polarity of aforesaid gain CPURITY1-GAIN, CPURITY2-GAIN, CPURITY3-GAIN, CPURITY4-GAIN, but also we can say the direction of four jiaos in the image of the mobile display surface 100 of expression.Wherein, as shown in figure 12, from left to right direction F is defined as just (+), and the opposite direction of direction F is defined as negative (-).And, as shown in figure 14, because the upper right and lower right-most portion of the image of mobile display surface 100 on direction F, upper left and the bottom left section of the image of mobile display surface 100 on the rightabout of direction F, so polarity number CPURITY1-POL, CPURITY4-POL are set at+1, and CPURITY2-POL, CPURITY3-POL are set at-1.In addition, as shown in figure 21, from the state that recovers fully of deterioration of screen during reach capacity, degradation value TDS only change 140 (=240-100).During this period, be necessary to make the image of display surface 100 only to change for four jiaos | 10 μ m|.Only change for four jiaos at the image that makes display surface 100 | during 10 μ m|,, be necessary to make correcting current value change 10mA according to above-mentioned results measured.When making correcting current value change 10mA, be necessary to make current value cpurity1, cpurity2, cpurity3, cpurity4 only to change 10 respectively.According to above situation, will gain CPURITY1-GAIN, CPURITY2-GAIN, CPURITY3-GAIN, CPURITY4-GAIN are set at 10/140 respectively.

For example, under the such situation of Figure 21, after power source ON, because the time time-delta=140 that reaches capacity, so if, become so with in each value substitution formula 1～formula 4

cpurity1＝ADJ-CPURITY1+{(10/140)×(+1)×140}

＝ADJ-CPURITY1+10

cpurity2＝ADJ-CPURITY2+{(10/140)×(-1)×140}

＝ADJ-CPURITY2-10

cpurity3＝ADJ-CPURITY3+{(10/140)×(-1)×140}

＝ADJ-CPURITY3-10

cpurity4＝ADJ-CPURITY4+{(10/140)×(+1)×140}

＝ADJ-CPURITY4+10

。And, in effluxion, because the time time-delta that reaches capacity is near zero, so constantly approaching

cpurity1＝ADJ-CPURITY1+{(10/140)×(+1)×0}

＝ADJ-CPURITY1

cpurity2＝ADJ-CPURITY2+{(10/140)×(-1)×0}

＝ADJ-CPURITY2

cpurity3＝ADJ-CPURITY3+{(10/140)×(-1)×0}

＝ADJ-CPURITY3

cpurity4＝ADJ-CPURITY4+{(10/140)×(+1)×0}

＝ADJ-CPURITY4

。And, if become saturation condition, there is not calc-cpurity subprogram S5 (Fig. 6) so, implementation step S4 becomes

cpurity1＝cpurity1-fact

cpurity2＝cpurity2-fact

cpurity3＝cpurity3-fact

cpurity4＝cpurity4-fact。

Then, essential parameter is polarity number HSTA-POL, gain HSTA-GAIN, corrected value hata-fact not in convergence correction step HSS.

Specifically, consider situation about 24 elapsed time of cathode ray tube, changing as shown in Figure 16.After power source ON, the red line RL that is presented at the image on the display surface 100 is in the right of desired locations, and the blue line BL that is presented at the image on the display surface 100 is in the left side of desired locations, is 1.0mm apart from the variable quantity of its desired locations.In addition, from power source ON, through adequate time, the red line RL of display surface 100 and blue line BL are in the position (being that variable quantity is 0mm) of expectation.

Under the situation of above-mentioned concrete example, if enumerate an example that begins often to keep optimum state from power source ON, so at first on hardware, as Figure 15 and shown in Figure 4, to assemble correcting coil 12 is installed on the cathode ray tube 24, so that during the correcting current of the positive direction that flows in convergence correction coil 12, (direction F1) moves blue line BL, (direction F2) mobile red line RL from left to right from right to left.In addition, change ± 1, carry out circuit design so, make the correcting current value variation ± 1.0mA of driver 7 outputs if input to the current value hsta of D/A converter 20 (Fig. 5).And, be that if current value hsta changes ± 1, red line RL and blue line BL only move so for the measured result of the cathode-ray tube displaying device of making | the absolute value of 0.01mm|.In addition, degradation value TDS as shown in figure 21.In this case, press

HSTA-POL＝-1

HSTA-GAIN＝10/140

Set.

As mentioned above, polarity number HSTA-POL represents the polarity of HSTA-GAIN that gains, but also we can say the direction that expression red line RL and blue line BL move.Wherein, as shown in figure 15, for red line RL, direction F2 just is being defined as (+1), and the opposite direction F1 of direction F2 is being defined as negative (1).On the other hand, for blue line BL, direction F1 just is being defined as (+1), and direction F2 is being defined as negative (1).And as shown in figure 17, because the red line RL of display surface 100 moves on direction F1, blue line BL moves on direction F2, so polarity number HSTA-POL is set at-1.In addition, as shown in figure 21, the state that recovers fully from the deterioration of assembling during reach capacity, degradation value TDS only change 140 (=240-100).During this period, be necessary to make the red line RL of display surface 100 and blue line BL only to change | 0.1mm|.Only change at red line RL that makes display surface 100 and blue line BL | during 0.1mm|,, be necessary to make correcting current value change 10mA according to above-mentioned results measured.When making correcting current value change 10mA, be necessary to make current value hsta only to change 10.According to above situation, the HSTA-GAIN that will gain is set at 10/140.

For example, under the such situation of Figure 21, after power source ON, because the time time-delta=140 that reaches capacity, so if general's value substitution formula 5 separately, so

hsta＝ADJ-HSTA+{(10/140)×(-1)×140}

＝ADJ-HSTA-10

And owing to the increase along with the time, the time time-delta that reaches capacity is near zero, so approaching

hsta＝ADJ-HSTA+{(10/140)×(-1)×0}

＝ADJ-HSTA

And, if become saturation condition, do not have calc-hsta subprogram S8 (Fig. 6) so, and implementation step S7 becomes

hsta＝hsta-fact。

Then, necessary parameter is polarity number HPOSI-POL, gain HPOSI-GAIN, corrected value hposi-fact not in horizontal image position correction step HPS.

Specifically, consider that cathode ray tube 24 increases situation about changing as shown in Figure 19 in time.After power source ON, be presented at the right that image 101 on the display surface 100 is in desired locations, its variable quantity is 1.0mm.In addition, from power source ON, through adequate time, the image 101 of display surface 100 is in the position (being that variable quantity is 0mm) of expectation.

Under the situation of above-mentioned concrete example, if enumerate an example that begins often to keep optimum state from power source ON, so at first on hardware, as Figure 18 and shown in Figure 4, deflecting coil 23 is installed on the cathode ray tube 24, so that during the correcting current of the positive direction that in deflecting coil 23, flows, move image 101 towards the direction of arrow F.In addition, change ± 1, carry out circuit design so, make the correcting current value variation ± 1.0mA of driver 22 outputs if input to the current value hposi of D/A converter 21 (Fig. 5).Therefore, the measured result for the cathode-ray tube displaying device of making is that if current value hposi changes ± 1, the image of display surface 100 only moves so | the absolute value of 0.01mm|.In addition, degradation value TDS as shown in figure 21.In this case, can by

HPOSI-POL＝-1

HPOSI-GAIN＝10/140

Set.

As mentioned above, polarity number HPOSI-POL represents the polarity of HPOSI-GAIN that gains, but also we can say the direction that expression is moved the image 101 of display surface 100.Wherein, as shown in figure 18, direction F just is being defined as (+1), and the opposite direction of direction F is being defined as negative (1).And, as shown in figure 20, because the image 101 of display surface 100 is moved up the negative side of direction F, so polarity number HPOSI-POL is set at-1.In addition, as shown in figure 21, the state that recovers fully from the deterioration of horizontal position of image during reach capacity, degradation value TDS only change 140 (=240-100).During this period, the image 101 of display surface 100 is only changed | 0.1mm|.Only change at the image 101 that makes display surface 100 | during 0.1mm|,, must make correcting current value change 10mA according to above-mentioned measured result.When making correcting current value change 10mA, be necessary to make current value hposi only to change 10.According to above situation, the HPOSI-GAIN that will gain is set at 10/140.

For example, under the such situation of Figure 21, after power source ON, because the time time-delta=140 that reaches capacity, so if general's value substitution formula 6 separately, so

hposi＝ADJ-HPOSI+{(10/140)×(-1)×140}

＝ADJ-HPOSI-10

And, along with the time increases, because the time time-delta that reaches capacity is near zero, so approaching

hposi-c＝ADJ-HPOSI+{(10/140)×(-1)×0}

＝ADJ-HPOSI

And, if become saturation condition, do not have calc-hposi subprogram S11 (Fig. 6) so, and execution in step S10 becomes:

hposi＝hposi-fact。

In above concrete example,,,, whole corrected values is redefined for zero owing to consider the situation that becomes optimum state even correcting current does not flow so if begin through adequate time from power source ON.Thus, begin along with the time increases from power source ON, correcting current is constantly near zero.And under saturation condition, can make the needed power consumption of image correcting is zero, and can keep optimum state.

In addition, as described above, with goods offer gain, polarity number before the market, corrected value, offset, desired value etc. all are not stored in the memory 13 in advance as data M D.Therefore, the interior memory 13 of perhaps changing by rewrite memory 13 can easily change these values.

In addition, in the inspection technology of the manufacturing process of cathode ray tube 24, in mass-produced a plurality of cathode ray tubes 24, compare with other cathode ray tube, even detect the degradation characteristic of position alignment cathode ray tube devious, if measure its memory 13 aging, that preparation is special-purpose for this cathode ray tube 24, memory 13 can absorb the degradation characteristic deviation of position alignment always so.Thus, no matter for which cathode ray tube 24, can obtain same visual display result.

Variation

Have again, in the above-described embodiments, the situation that gain CPURITY1-GAIN, CPURITY2-GAIN, CPURITY3-GAIN, the CPURITY4-GAIN of formula 1～formula 4 are equal to each other has been described, but also can have changed formula 1～formula 4 respectively.Therefore, four jiaos that also can adapt at the display surface 100 of cathode ray tube 24 change different situations.In addition, illustrated that polarity number CPURITY1-POL, CPURITY2-POL, CPURITY3-POL, CPURITY4-POL, HSTA-POL, HPOSI-POL are two kinds of situations of (+1) and (1), but for example also (for example can be set at software, formula 1～formula 4 changes) or hardware is (for example, first～the 4th the screen correcting coil 8～11 change), make it all become (+1).

In addition, as shown in figure 22, the situation that hypothesis gain HSTA-GAIN equates on the whole zone of the display surface 100 of cathode ray tube 24 has been described, but as shown in figure 23, it is synchronous also can be set at the visual horizontal deflection signal HSYNC that current value hsta and cathode ray tube 24 are shown, the left side of pressing display surface 100 a horizontal period is different with the right side.Thus, also it assembles the situation inequality that changes corresponding to the left side of cathode ray tube 24 display surfaces 100 and right side.

In addition, illustrated means for correcting C comprise first～the 4th the whole situation of screen correcting coil 8～11, convergence correction coil 12 and deflecting coil 23, but also can comprise first～the 4th at least one in screen correcting coil 8～11, convergence correction coil 12 and the deflecting coil 23.

In addition, the TIMER-ENABLE step S17 of the CPURITY-ENABLE step S3 of Fig. 6, HSTA-ENABLE step S6, HPOSI-ENABLE step S9 and Fig. 8 is by relatively degradation value cr-steady and expected value cr-center select yes, no, but utilize other method, also can select yes, the no of CPURITY-ENABLE step S3, HSTA-ENABLE step S6, HPOSI-ENABLE step S9 and TIMER-ENABLE step S17, for example, the user can select yes, no.

And, because correcting current through monotone decreasing is few after a while, promptly do not increase and reduces, thus also can comprise current value identical during.

According to scheme 1 described invention, along with the time increases, correcting current diminishes.Therefore, because along with the time increases and can reduce the needed power consumption of image correcting, so the power consumption can suppress to use for a long time the time.

According to scheme 2 described inventions, according to the feature of cathode ray tube, behind the power supply of connecting cathode ray tube, along with the time increases, the ratio that deterioration increases constantly reduces.Relative therewith, along with the time increases, the minimizing ratio of correcting current constantly reduces.Therefore, can suitably proofread and correct the image of cathode ray tube.

According to scheme 3 described inventions, from energized, if through adequate time, so owing to the correcting current vanishing, so can make the needed power consumption vanishing of image correcting.

According to scheme 4 described inventions, can reduce screen, convergence or the needed power consumption of horizontal image position correction.

According to scheme 5 described inventions, along with the time increases, driver can reduce correcting current.Therefore, owing to, can reduce the power consumption of means for correcting, so the power consumption can suppress to use for a long time the time along with the time increases.

According to scheme 6 described inventions, according to the feature of cathode ray tube, behind the power supply of connecting cathode ray tube, along with the time increases, the ratio that deterioration increases constantly reduces.Relative therewith, along with the time increases, the ratio that the correcting current of driver output reduces constantly reduces.Therefore, can suitably proofread and correct the image of cathode ray tube.

According to scheme 7 described inventions, from energized, if through adequate time, the correcting current vanishing of exporting owing to driver so is so can make the required power consumption of image correcting reach zero.

According to scheme 8 described inventions, can reduce to shield the power consumption of correcting coil, convergence correction coil or horizontal image position correction system.

According to scheme 9 described inventions, offer outside terminal by data with corresponding cathode ray tube, the best that can easily carry out on cathode ray tube is proofreaied and correct.

According to scheme 10 described inventions, the power consumption when cathode-ray tube displaying device is used for a long time diminishes.

Claims (10)

1. image correcting method, by supplying with correcting current to cathode ray tube, the image from dynamic(al) correction shows on described cathode ray tube is characterized in that,

During behind the power supply of connecting described cathode ray tube at least 3 hours, make the dull minimizing of described correcting current.

2. image correcting method as claimed in claim 1 is characterized in that,

Behind the power supply of connecting described cathode ray tube, along with the time increases, the ratio that reduces of described correcting current constantly reduces.

3. image correcting method as claimed in claim 1 is characterized in that,

Behind the power supply of connecting described cathode ray tube, make described correcting current constantly near zero.

4. image correcting method as claimed in claim 1 is characterized in that,

Comprising in screen, convergence and the horizontal position of image at least one from the object of the described image of dynamic(al) correction.

5. picture correction apparatus, by supplying with correcting current to cathode ray tube, the image that shows on the described cathode ray tube of dynamic(al) correction is characterized in that,

Comprise:

Counting circuit is calculated described correcting current value, makes during behind the power supply of connecting described cathode ray tube at least 3 hours, and described correcting current is dull to be reduced,

Driver, according to the result that calculates of described counting circuit, generate and export described correcting current and

Adjuster is arranged on the described cathode ray tube, accepts the described correcting current from described driver, proofreaies and correct the image that shows on the described cathode ray tube.

6. picture correction apparatus as claimed in claim 5 is characterized in that,

Behind the power supply of connecting described cathode ray tube, described counting circuit is calculated described correcting current value, so that along with the time increases, constantly reduce the minimizing ratio of described correcting current.

7. picture correction apparatus as claimed in claim 5 is characterized in that,

From connecting the power supply of described cathode ray tube, described counting circuit is calculated described correcting current value, so that make described correcting current constantly near zero.

8. picture correction apparatus as claimed in claim 5 is characterized in that,

Described means for correcting is comprising at least one of shielding in correcting coil, convergence correction coil and the horizontal image position correction deflecting coil.

9. picture correction apparatus as claimed in claim 5 is characterized in that,

Described counting circuit also comprises in order to calculate described correcting current value provides the outside terminal of necessary data from the outside.

10. a cathode-ray tube displaying device comprises each described picture correction apparatus and described cathode ray tube in the claim 5 to 9.

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